Location: Floral and Nursery Plants Research
Project Number: 8020-21000-147-04-S
Project Type: Non-Assistance Cooperative Agreement
Start Date: Sep 1, 2011
End Date: Oct 30, 2014
The objective of this study is to apply DNA microsatellite diversity to craft a more efficient sampling strategy for the preservation of genetic diversity of green ash trees in Ohio and surrounding states. In addition, this study will also provide guidelines for the future establishment of a core collection of green ash; i.e., a set of accessions selected to represent a high proportion of the genetic diversity of the overall collection.
Microsatellite markers are useful tools for examining breeding systems and patterns of variation within populations, for differentiating among accessions/populations, and for marker-aided selection and gene introgression. In particular, microsatellites can be used to identify individual accessions with a high relative contribution to overall allelic diversity among a set of accession/populations in a germplasm collection. Moreover, microsatellite markers can be used to quantify genetic diversity and its distribution across the landscape, as well as to help define mating structure. Green ash (Fraxinus pennsylvanica) is one of the most widely planted and adaptable street trees in the Midwest. As with the other species of ash native to eastern North America, it is currently under direct threat from Emerald Ash Borer (EAB). The Cooperators are based in Ohio, and are researching the population genetics of ash trees during the course of the EAB outbreak. The information to be generated by this study is fundamental for the establishment of a sampling protocol for the ex situ conservation of green ash diversity and its evolutionary potential. More specifically, the knowledge of genetic structure can help direct sampling efforts for specific plant traits, such as host-tree resistance to pathogens and herbivores. It is our objective to use at least ten microsatellite marker loci to determine the levels and distribution of genetic diversity of green ash trees in the four of the five major physiographic regions of Ohio. We proposed to analyze a sub-sample of the seeds of green ash already incorporated into the US National Plant Germplasm System (NPGS), along with new material currently being collected in Ohio.